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Page 1: UNIVERSITI TEKNIKAL MALAYSIA MELAKA - eprints.utem.edu.myeprints.utem.edu.my/2285/1/Mechanical_Properties_Determination_Of_Mild... · Walaubagaimanapun, ujian struktur micro menunjukkan
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UNIVERSITI TEKNIKAL MALAYSIA MELAKA

BORANG PENGESAHAN STATUS LAPORAN PROJEK SARJANA MUDA

TAJUK: Mechanical properties determination of mild steel and stainless steel

joint fabricated by MIG welding process

SESI PENGAJIAN: 2009/10 Semester 2

Saya SHAHRIR BIN SAHARI

mengaku membenarkan Laporan PSM ini disimpan di Perpustakaan Universiti Teknikal Malaysia Melaka (UTeM) dengan syarat-syarat kegunaan seperti berikut:

1. Laporan PSM adalah hak milik Universiti Teknikal Malaysia Melaka dan penulis. 2. Perpustakaan Universiti Teknikal Malaysia Melaka dibenarkan membuat salinan

untuk tujuan pengajian sahaja dengan izin penulis. 3. Perpustakaan dibenarkan membuat salinan laporan PSM ini sebagai bahan

pertukaran antara institusi pengajian tinggi.

4. **Sila tandakan (√)

SULIT

TERHAD

TIDAK TERHAD

(Mengandungi maklumat yang berdarjah keselamatan atau kepentingan Malaysia yang termaktub di dalam

AKTA RAHSIA RASMI 1972)

(Mengandungi maklumat TERHAD yang telah ditentukan

oleh organisasi/badan di mana penyelidikan dijalankan)

Alamat Tetap:

Lot 156 Kg Baru Peramu,

26060 Kuantan,

Pahang Darul Makmur.

Tarikh: _________________________

Disahkan oleh:

Cop Rasmi: Tarikh: _______________________

** Jika Laporan PSM ini SULIT atau TERHAD, sila lampirkan surat daripada pihak berkuasa/organisasi berkenaan dengan menyatakan sekali sebab dan tempoh laporan PSM ini perlu dikelaskan sebagai

SULIT atau TERHAD.

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DECLARATION

I hereby, declared this report entitled “Mechanical properties determination of mild steel

and stainless steel joint fabricated by MIG welding process

” is the results of my own research except as cited in references

Signature : …………………………………………….

Author’s Name : …………………………………………….

Date : …………………………………………….

SHAHRIR BIN SAHARI

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APPROVAL

This report is submitted to the Faculty of Manufacturing Engineering of UTeM as a

partial fulfillment of the requirements for the degree of Bachelor of Manufacturing

Engineering (Manufacturing Process) with Honours. The member of the supervisory

committee is as follow:

(Signature of Supervisor)

……..………………………………

(Official Stamp of Supervisor)

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ABSTRAK

Tujuan projek ini adalah untuk menentukan prilaku mekanik dan daerah terkesan haba

(HAZ) pada struktur mikro, terhadap kimpalan diantara besi baja yang mengandungi

peratusan yang karbon rendah dan keluli tahan karat dengan menggunakan proses

kimpalan keluli gas arka (MIG). Keluli tahan karat daripada kelas (AISI 304) dah besi

baja karbon rendah (AISI 1010) telah digunakan dalam projek ini. Kedua-duanya yang

berketeblan 4 mm telah dikimpal bersama logam penambah (AWS ER309) yang berbeza

diameter iaitu (0.8 mm dan 1.2 mm). Mesin kimpal (WIM 210S) telah digunakan untuk

tujuan tersebut, yang mana parameter terkawal adalah voltan, kelajuan suap logam

penambah dan kadar alir gas pelindung. Ujian – ujian mekanik yang dilaksanakan adalah

ujian kekuatan tarikan, ujian keteguhan hentaman, dan ujian kekerasan. Di penghujung

analisa didapati terdapat perubahan nilai kekerasan pada setiap bahagian seperti besi

asas, kawasan terkesan haba dah bahagian kimpalan itu sendiri. Kekerasan yang tinggi

telah dicatat pada kawasan terkesan haba di kedua- dua belah sambungan. Ujian terikan

pula menunjukkan kimpalan menggunakan logam penambah berdiameter 0.8 mm adalah

lebih tegar daripada 1.2 mm. Sungguhpun begitu, kesemua bahan ujian telah gagal pada

kawasan terkesan haba di sebelah (AISI 1010) yang berkemungkinan disebabkan oleh

kurangnya pelakuran antara logam penambah dan besi baja karbon rendah.

Walaubagaimanapun, ujian struktur micro menunjukkan adanya keretakan berlaku pada

bahagian HAZ tersebut yang menyumbang pada kegagalan semasa ujian keterikan.

Akhir sekali, tumpuan haruslah diberikan sepenuhnya terhadap rekabentuk, procedur,

spesifikasi dan teknik mengimpal besi yang berlainan jenis untuk mendapat keputusan

yang baik sebelum berjaya menentukan penetapan perilaku mekanik terhadap sesuatu

sambungan kimpalan.

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ABSTRACT

The purpose of this study is to determine the mechanical properties and the

microstructure behavior at weldment and HAZ of mild steel and stainless steel joint

fabricated using MIG welding process. Material from grade Austenitic stainless steel

(AISI 304) and mild steel (AISI 1010) with both thickness 4 mm were used. Welding

design was done in single groove butt joint and weld using 1.2 mm and 0.8 mm diameter

size of filler wire (ER309). Welding machine (WIM 210S) was used with selected

parameter with involved voltage, wire feed speed and gas flow rate. Mechanical

properties were evaluated in tensile tests, Charpy-V toughness tests, and hardness test. In

addition microstructure examinations were carried out. Base on the finding, there was

changes in hardness value on base metal, weldment and HAZ area. High hardness value

has been identified at both HAZ area of dissimilar weld. Tensile test show at 1.2 mm

strength was weaker than 0.8 mm joint. All specimens were fracture at HAZ near AISI

1010 side because of lack of fusion. At their barrier microstructures reveal that present

of crack at HAZ near AISI 1010 and show little dilution in intermetallic of dissimilar

metal. No ferrite structure present because MIG welding provide rapid cooling. All the

implication in the dissimilar weld disturbance and affect the whole properties.

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ACKNOWLEDGEMENTS

First and foremost, I would like to thank Almighty Allah for allowing me to successfully

complete this report. I also would like to convey my thanks to the all person who had

contributed in ensuring a successful occurrence throughout the duration of my final year

project. I also would like to take this opportunity to express my gratitude to Mr. Mohd

Shukor bin Salleh as my supervisor for his guidance and support. I also want to express

my whole-hearted thanks to all my friends who are also my comrades in times of need.

Last but not list those mentioned, I would like to express my gratitude with highly

appreciation and dedication to my family with their support morally in completing my

final year project and motivate to success and complete study in Universiti Teknikal

Malaysia, Melaka (UTeM).

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TABLE OF CONTENTS

Abstract i

Abstrak ii

Dedication iii

Acknowledgement iv

Table of Contents v

List of Figures ix

List of Tables xii

List of Abbreviations xiii

CHAPTER 1: INTRODUCTION

1.1 Introduction 1

1.2 Project Background 3

1.3 Problem Statement 4

1.4 Objective 6

1.5 Scope of Project 6

1.6 Report Organization 7

1.7 Project Planning 7

CHAPTER 2: LITERATURE REVIEW

2.0 Introduction 8

2.1 Stainless Steel 10

2.1.1 Typical Stainless Steel Application 10

2.1.2 Austenitic (200 and 300 series) 11

2.2 Low Carbon Steel (Mild Steel) 12

2.2.1 Typical Mild Steel Application 12

2.3 Gas Metal Arc Welding (GMAW) 13

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2.3.1 MIG Metal Transfer 14

2.3.1.1 Spray Transfer 14

2.3.1.2 Globular Transfer 15

2.3.1.3 Short Circuiting Transfer 15

2.3.2 MIG Equipment Setup 16

2.3.3 Principles of Operation 17

2.4 Dissimilar Metal Welding 18

2.4.1 Weld Metal 18

2.4.2 Dilution 19

2.4.3 Melting Temperature 19

2.4.4 Thermal Conductivity 19

2.4.5 Coefficient of Thermal Expansion 19

2.5 Welding Stainless Steel and Mild Steel 20

2.6 Welding Consideration 20

2.6.1 Filler Wire Selection for Dissimilar Metal 20

2.6.2 Buttering Process 22

2.6.3 Joint Design for MIG 23

2.6.4 Butt Joint 23

2.6.5 Shielding Gas 24

2.7 Variation for MIG welding Process 25

2.8 Mechanical Properties 25

2.8.1 Tensile Test 26

2.8.2 Stress –Strain Curves 26

2.8.3 Basic Calculation 27

2.8.4 Ductility 28

2.9 Hardness Test 28

2.9.1 Rockwell hardness test 29

2.10 Impact Test 29

2.10.1 Toughness 30

2.11 Weldment Microstructure 30

2.12 Heat Affected Zone 32

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CHAPTER 3: METHODOLOGY

3.0 Introduction 34

3.1 Process Flow Chart 35

3.2 Materials preparation 36

3.2.1 Raw Material 36

3.3 Equipment preparation 37

3.4 Design of Experiment (D.O.E) 38

3.4.1 Determine MIG welding Settings 38

3.4.2 Procedure of Hardness Measure 39

3.5 Machine Setup 40

3.5.1 Install Filler wire 40

3.5.2 Contact Tip Change 41

3.6 Welding Experiment 41

3.6.1 Cutting the Material 41

3.6.2 Joint Design Process 42

3.6.3 Buttering Process 42

3.6.4 Tack Weld process 43

3.6.5 Welding process 43

3.7 Specimen Preparation 44

3.7. 1 Cutting process 45

3.7.2 Tensile Specimen (ASTM E8) 45

3.7.3 Hardness Specimen (ASTM 10) 46

3.7.4 Microstructure Specimen (ASTM E3) 47

3.7.5 Impact Specimen (ASTM E23) 48

3.8 Experimentation 48

3.8.1 Hardness Test Measurement 49

3.8.2 Tensile Test Measurement 49

3.8.3 Impact Test Measurement 50

3.8.4 Microstructure Analysis 51

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CHAPTER 4: RESULT AND DISCUSSION

4.1 Hardness Result-D.O.E 53

4.2 Actual Experiment 56

4.3 Hardness Result 56

4.3.1 Hardness Data Analysis 57

4.4 Results for Tensile Test 59

4.4.1 Data Collected Analysis 60

4.4.2 Stress versus Strain Analysis 61

4.5 Results for Charpy Impact 63

4.6 Results for Microstructure Analysis 64

4.6.1 Sample A -Filler wire 1.2 mm with 20X Magnifier 64

4.6.2 Sample F- Filler wire 0.8 mm with 20X Magnifier 65

4.7 Relation of the Results 67

CHAPTER 5: CONCLUSION AND RECOMMENDATION

5.0 Introduction 68

5.1 Result overview 68

5.2 Conclusion 69

5.3 Recommendation 70

REFERENCES 71

APPENDICES

A Gantt chat

B Hardness test result

B Tensile test result

D Microstructure Analysis

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LIST OF FIGURES

1.0 Dissimilar metal joint in Volvo S40 3

2.1 Basic principle of MIG welding 13

2.2 Spray transfer 14

2.3 Globular transfer. 15

2.4 Short-circuiting transfer. 16

2.5 Schematic of equipment setup for MIG 16

2.6 Illustration operation of MIG 17

2.7 Effect of electrode position and welding technique. 17

2.8 A Schaeffler diagram and the procedure of estimating the 21

microstructure of E309-type.

2.9 Buttering process used to assist in dissimilar welding 22

2.10 Bevel angle, groove angle, and root opening of joints for welding. 23

2.11 Shielding gas related to weld profile for DCEP 24

2.12 Diagram of tensile test machine 26

2.13 Typical stress-strain curve obtained from tensile test. 27

2.14 Rockwell hardness testing technique. 29

2.15 Charpy-V notch impact apparatus. 30

2.16 Optical microstructure of parent metal Austenite 304 stainless steel. 31

2.17 Optical microstructure of parent metal plain mild steel. 31

2.18 Heat affected zone microstructure Austenitic steel side. 31

2.19 Anatomy of a weld. 32

3.1 Process Flow Chart 35

3.2 Stainless steel plate 36

3.3 Mild Steel Plate 36

3.4 Filler Wire specification 37

3.5 MIG Machine Specification 37

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3.6 Hardness measured point for D.O.E purpose 39

3.7 Hardness test in progress 39

3.8 Show the sequence to install the filler wire 40

3.9 Procedure to change the MIG contact tip 41

3.10 Beveling process. 42

3.11 Buttering process at AISI 1010 side 42

3.12 Allocated the tack weld. 43

3.13 MIG welding in action 43

3.14 Finish welded part with 45 degree single groove butt join type 44

3.15 The way specimen cut from weld part 44

3.16 Cutting the specimen for testing 45

3.17 Standard specimen for tensile test 45

3.18 Tensile specimen for 1.2 mm diameter filler wire 46

3.19 Example of hardness test specimen 46

3.20 Hardness test specimens 47

3.21 Metallographic specimens. 47

3.22 Specimen for charpy impact test 48

3.23 Rockwell hardness machine 49

3.24 Hardness test process 49

3.25 Tensile machine in progress 50

3.26 Impact Tester 51

3.27 Specimen with before and after impact test 51

3.28 Image Analyzer (Buehler Omniment). 52

3.29 Grinding and polishing equipment (Buehler). 52

4.1 Hardness Result for 1.2 mm filler wire 53

4.2 Hardness Result for 0.8 mm filler wire 54

4.3 Hardness measure point 54

4.4 Mean of hardness value on dissimilar metal joint. 57

4.5 Tension test specimen 59

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4.6 Properties comparison between different size filler wire. 60

4.7 Result tension test for specimen A 61

4.8 Result tension test for specimen F 62

4.9 Show the Result obtain from Charpy test 63

4.10 Physical appearance of the specimen after the test 63

4.11 Metallographic observation on 1.2 mm (20 X) 64

4.12 Metallographic observation on 0.8 mm (20 X) 65

4.13 Heat Affected zone (HAZ) and weldment 66

4.14 Solidification Crack was identifying using both filler wire. 67

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LIST OF TABLES

2.1 Minimum Mechanical Properties for annealed Alloys 11

2.2 Nominal Compositions of Austenitic Stainless Steels. 11

2.3 Mechanical properties of selected carbon steel. 12

2.4 Composition of selected carbon steel. 12

2.5 The nominal chemical compositions of the alloy steel 21

2.6 Mechanical properties of ER309 21

2.7 Recommended parameter for MIG using welding grade CO2 22

2.8 The variation of the MIG welding process. 25

2.9 Recommended etching solution for dissimilar metal 32

3.1 General setting parameter for MIG welding process 38

3.2 Best Parameter for Welding machine MIG 210S 40

3.3 Standard specimen size for tensile experiment (From ASTM E8) 46

3.4 Parameter for Hardness test machine 49

3.5 Parameter for tensile test machine 50

4.1 MIG parameter for 1.2 mm filler wire 55

4.2 MIG parameter for 0.8 mm filler wire 55

4.3 Specimen number for each filler wire 56

4.4 Convert HRB value to approximate tensile strength 58

4.5 Data of tensile test using 1.2 mm and 0.8 mm MIG filler wire 60

5.1 Mechanical properties 69

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LIST OF ABBREVIATIONS

AWS - American Welding Society

AISI - American Iron and Steel Institute

ASTM - American Standard Testing for Material

ASME - American Society of Mechanical Engineer

BHN - Brinell Hardness Number

Cr - Chromium

CV - Constant Voltage

CO2 - Carbon dioxide

DCEP - Direct Current Electrode positive

DCEN - Direct Current Electrode Negative

GTAW - Gas Tungsten Arc Welding

GMAW - Gas Metal Arc Welding

HAZ - Heat Affected Zone

MIG - Metal Inert Gas

Mn - Manganese

Ni - Nickel

PSM - Projek Sarjana Muda

SMAW - Shield Metal Arc Welding

SAW - Submerge Arc Welding

UTeM - Universiti Teknikal Malaysia Melaka

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CHAPTER 1

INTRODUCTION

1.1 Introduction

Welding is very common technique in order to join two or more types of metal. Welding

is used to join all commercial metals and alloys and to joint metal of different type of

strength. Welding begin as a repair or maintenance tool and has become one of the most

crucial manufacturing methods as well as the most essential construction method.

Almost everything made of metal is welded. Because of its strength and versatility,

welding is used in manufacture of almost all the products used in our life every day.

Without welding many community cannot afford the cost of the goods and services they

need to earn a living (Cary & Helzer, 2005).

American welding society (AWS) has defined welding as “a joining process that

produce coalescence of materials by heating them to the welding temperature, with or

without the application of pressure or by the application of pressure alone, and with or

without the use of filler metal”. Welding goes well beyond the bounds of its simple

description. Welding today is applied to a wide variety of materials and products, using

such advanced technologies such as lasers and plasma arcs. The future of welding holds

even greater promise as methods are devised for joining dissimilar and non-metallic

materials, and for creating products of innovative shapes and designs.

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For an example, the famous trans-Alaska pipeline, a super-tanker, the world largest

moving weldment, storage tank for water supply systems, the sears Tower in Chicago

would not be possible without welding. The international space station was welded

together on earth and transported to space, and the final assembly welds were done in

space. The shuttle itself, from the rocket engines to the external fuel tank, required

specialized procedures for welding alloy aluminum without defects. Most large airplanes

include much welding, even miniature components for electronic equipment and

telecommunication equipment. All of these prove that welding is important in many

applications (Cary & Helzer, 2005).

There are many types of welding processes and also many ways to make a weld. Some

welding processes do not cause spark, use electricity, or required heat. Many different

energy sources can be used for welding, including a gas flame, an electric arc, a laser, an

electron beam, friction, and ultrasound. While often an industrial process, welding can

be done in many different environments, including open air, under water and in outer

space (Cary & Helzer, 2005).

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1.2 Project Background

Welded dissimilar metal joints become widely accepted as the superior design option for

manufactured products between their quality, reliability, and serviceability. The welding

industries are working to remove reservations in areas where there is concern about

welded joints due to limitations of materials, process, and ability to ensure quality. In the

recent years, welding dissimilar metal joint promotes various service conditions such as

resistance to corrosion, heat resistance and magnetic properties. A lot of study has been

done with the dissimilar welding technology nowadays.

Wagner et al. (2000) shows there were a lot of wide variety of possible applications for

dissimilar material combinations. At present, the main focus in this area is aiming car

body concepts for weight reduction and higher stiffness due to the locally use of

aluminum sheet materials. For power train components the combination of aluminum

parts with thin walled steel pipes offers the opportunity for a significant reduction of the

rotating masses. Under this concern, higher product efficiency could be realized.

Figure 1.0: Dissimilar metal joint in Volvo S40 (Available at: http://www.designnews.com).

Realizing the important of welding dissimilar metal nowadays; the research about

joining the material of mild steel and stainless steel fabricated by using MIG welding

process has been carrying out. In contrast, this research is subjected to determine the

mechanical properties of dissimilar metal joint and also to study the characteristic of the

weldment area. This is important to understand behavior of dissimilar joint at the basic

point of view before applying them to the real application.

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1.3 Problem Statement

Weld between dissimilar metals relates to the transition zone between the metal and the

intermetallic compounds formed in this transition zone. For the fusion welding

processes, it is important to investigate the composition of two metals involved. If there

is mutual solubility of the two metals, the dissimilar joint can be made successfully. If

there is little or no solubility between the two metals to be joined, the weld joint will not

be successful (Cary & Helzer, 2005).

Al Wadleigh (1991) derive dissimilar metals have different chemistries, so they have

different physical properties such as melting temperature. Many who have involved with

joining metal with different melt temperature experience frustration. The difficulties was

arise when someone try to melt metal together at same weld temperature. For example

mild steel and stainless steel, obviously in nature these materials have different melting

point.

MIG welding is widely used in many industry applications such as automotive, oil and

gas, agriculture, and construction. Their versatility, rapid, economical, capable in all

weld position, technique, speed and high deposition is the reason why it most used. MIG

welding can operate with semiautomatic or automatic and work with most metal

(Kalpakjian & Schmid, 2006).

MIG welding does not require particular skill level and it is capable to be carried out by

fresh welder with some basic instruction. Hence, it is provided with semiautomatic mode

which is appropriate to reduce the human factor error that contributes to weld quality as

well as to acquire the better result. In weld a dissimilar metal, MIG welding is twice

better than SMAW in term of productivity from deposition of the welt metal on the base

metal, and good consumable utilization (Cary & Helzer, 2005).

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Kiling (2001) stated that scope of application of MIG welding in German is over 75%

nowadays, it is being used in partial mechanized, fully mechanized and automate

technique. MIG welding produce high quality weld at high speed without the used flux

and limited postweld cleaning. It is very desirable for both small and high production

metal joining. It frequently replaces other joining process such as riveting, brazing,

silver-soldering, or resistance welding. MIG welding is better than friction welding in

term of flexibility because friction welding constraint for round billet shape or pipe only.

It may be used instead of the following fusion welding process; submerge arc welding,

flux core and gas tungsten arc welding.

However material such Mild steel and stainless steel are widely used in many

applications such as construction, power plant, petrochemical, offshore, and more. Mild

steel is low carbon steel that easy to form and has excellent weldability meanwhile

stainless steel has popular as resistant to corrosion material and weldable with various

application (Kalpakjian & Schmid, 2006).

Realizing the important on joining dissimilar metal and its application in many industry

nowadays it is essential to joining various of metal in order to reducing cost and meet

the specification of the product. Engineer is essential to study the properties of the weld

join in order to design and size the load carrying for economic and safety concern.

Hence, the study on the mechanical properties determination of mild steel and stainless

steel joint fabricated by MIG welding process was necessary to provide understanding of

dissimilar weldments from the basic point of view.

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1.4 Objective

The objectives of the research are as follow:

a) To study the effect on mild steel and stainless steel joint using different

diameter filler wire of MIG welding.

b) To evaluate weld properties through the Hardness, Tensile, and

Microstructure.

c) To analyze the characteristic of weldment and heat affected zone (HAZ)

microstructure.

1.5 Scope of Project

Here, scope act as the guidance that permits this research is doing without loss the

focusing. It is capable to bring the project to their objective without run out by doing

work that not relate to the objective. Welding process has done using MIG welding

machine (WIM 210S). Three controlled parameter such Voltage, Wire feed and Gas

flow rate was selected which respect to the welding standard and machine capability.

Material used is from type (AISI 1010) mild steel and (AISI 304) stainless steel with

both thickness 4 mm. the joint design was single groove butt joint with flat position (1G)

by different diameter of MIG welding filler wire (ER309) which is 1.2 mm and 0.8 mm.

Specimen was prepared according to AWS and ASTM respectively to study the

mechanical properties such state in the objective. Other variables are not mention here

become a limitation of this project scope.

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1.6 Report Organization

Chapter 1: Introduction

a) This chapter briefly explained the background of the project study, the objective

that want to achieved, the problem statement and finally whole project planning

through Gantt chart.

Chapter 2: Literature Review

a) This chapter was collection of research information that relate to the study from

any trusted resources.

Chapter 3: Research Methodology

a) This chapter explains the structure on how project was done

Chapter 4: Result and Discussion

a) The output from the study was precisely explain and discussed in this chapter.

Chapter 5: Conclusion and Recommendation

a) This chapter finally explains the achievement of whole project to compare with

objectives.

1.7 Project Planning

The purpose of the project planning was to meet the due date. Besides that, it was very

important tool to manage the project smoothly and flexible. Although, Gantt chat was

developed for that purpose, it shows the time line for every task and targeted plan. From

Gantt chart the entire process was clearly preview, and the way to start the project was

easy to understand. Hence, Gantt chart was attached at Appendix A.